Open AccessAtmospheric Pressure Plasma Treatment of Aqueous Bisphenol A Solution
Author(s) -
JinOh Jo,
Kyeong Yun Choi,
Suji Gim,
Young Sun Mok
Publication year - 2015
Publication title -
applied chemistry for engineering
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.144
H-Index - 11
eISSN - 2288-4505
pISSN - 1225-0112
DOI - 10.14478/ace.2015.1029
Subject(s) - bisphenol a , aqueous solution , chemistry , formate , oxalate , mineralization (soil science) , ozone , decomposition , radical , volumetric flow rate , chromatography , analytical chemistry (journal) , inorganic chemistry , organic chemistry , catalysis , nitrogen , epoxy , physics , quantum mechanics
This work investigated the plasma treatment of aqueous bisphenol A (BPA) solution and mineralization pathways. For the effective contact between plasmatic gas and aqueous BPA solution, the plasma was created inside a porous ceramic tube, which was uniformly dispersed into the aqueous solution through micro-pores of the ceramic tube. Effects of the gas flow rate, applied voltage and treatment time on the decomposition of BPA were examined, and analyses using ultraviolet (UV) spectroscopy, ion chromatography and gas chromatography-mass spectrometry were also performed to elucidate mineralization mechanisms. The appropriate gas flow rate was around 1.0 L min -1 ; when the gas flow rate was too high or too low, the BPA decomposition performance at a given electric power decreased. The increase in the voltage improves the BPA decomposition due to the increased electric power, but the energy required to remove BPA was similar, regardless of the voltage. Under the condition of 1.0 L min
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